Review of solar-enabled desalination and implications for zero-liquid-discharge applications

Progress in Energy Pub Date : 2024-04-25 DOI:10.1088/2516-1083/ad43aa

V. Fthenakis, Pei Xu, Zhuoran Zhang, Kurban A. Sitterley, Abdiel Lugo, Huiyao Wang, Sarada Kuravi, Krishna Kota, Nikhil Dani, A. Atia, Parthiv Kurup, Ariel Miara

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Abstract

Production of fresh water from desalination of the abundant saline water on the planet is increasingly considered as a climate change adoption measure. Yet, there are challenges associated with the cost and environmental impact of desalination. Effective integration of solar energy generation and freshwater production can address both issues. This review article highlights recent key advances in such integration achieved in a joint-research university-national laboratory partnership under the auspices of the United States Department of Energy (DOE) and parallel efforts world-wide. First, an overview of current and emerging desalination technologies and associated pretreatment and brine management technologies that together can result in zero-liquid-discharge (ZLD) systems is presented and their technological readiness levels are evaluated. Then advanced modeling techniques and new software platforms that enable optimization of solar-desalination applications with the dual objective of cost and environmental impact minimization are discussed.

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太阳能海水淡化回顾及对零液体放电应用的影响

通过对地球上丰富的盐水进行海水淡化来生产淡水，越来越多地被认为是一种应对气候变化的措施。然而，海水淡化的成本和对环境的影响是一个挑战。有效整合太阳能发电和淡水生产可以解决这两个问题。这篇综述文章重点介绍了在美国能源部（DOE）的支持下，大学与国家实验室联合研究合作项目在这种整合方面取得的最新主要进展，以及全球范围内的并行努力。首先，文章概述了当前和新兴的海水淡化技术以及相关的预处理和盐水管理技术，这些技术可共同实现零液体排放（ZLD）系统，并对其技术就绪程度进行了评估。然后讨论了先进的建模技术和新的软件平台，这些技术和平台能够优化太阳能海水淡化应用，实现成本和环境影响最小化的双重目标。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Progress in Energy

CiteScore

18.20

自引率

0.00%

发文量